Mercurial > octave
view scripts/linear-algebra/expm.m @ 30875:5d3faba0342e
doc: Ensure documentation lists output argument when it exists for all m-files.
For new users of Octave it is best to show explicit calling forms
in the documentation and to show a return argument when it exists.
* bp-table.cc, shift.m, accumarray.m, accumdim.m, bincoeff.m, bitcmp.m,
bitget.m, bitset.m, blkdiag.m, celldisp.m, cplxpair.m, dblquad.m, flip.m,
fliplr.m, flipud.m, idivide.m, int2str.m, interpft.m, logspace.m, num2str.m,
polyarea.m, postpad.m, prepad.m, randi.m, repmat.m, rng.m, rot90.m, rotdim.m,
structfun.m, triplequad.m, uibuttongroup.m, uicontrol.m, uipanel.m,
uipushtool.m, uitoggletool.m, uitoolbar.m, waitforbuttonpress.m, help.m,
__additional_help_message__.m, hsv.m, im2double.m, im2frame.m, javachk.m,
usejava.m, argnames.m, char.m, formula.m, inline.m, __vectorize__.m, findstr.m,
flipdim.m, strmatch.m, vectorize.m, commutation_matrix.m, cond.m, cross.m,
duplication_matrix.m, expm.m, orth.m, rank.m, rref.m, trace.m, vech.m, cast.m,
compare_versions.m, delete.m, dir.m, fileattrib.m, grabcode.m, gunzip.m,
inputname.m, license.m, list_primes.m, ls.m, mexext.m, movefile.m,
namelengthmax.m, nargoutchk.m, nthargout.m, substruct.m, swapbytes.m, ver.m,
verLessThan.m, what.m, fminunc.m, fsolve.m, fzero.m, optimget.m, __fdjac__.m,
matlabroot.m, savepath.m, campos.m, camroll.m, camtarget.m, camup.m, camva.m,
camzoom.m, clabel.m, diffuse.m, legend.m, orient.m, rticks.m, specular.m,
thetaticks.m, xlim.m, xtickangle.m, xticklabels.m, xticks.m, ylim.m,
ytickangle.m, yticklabels.m, yticks.m, zlim.m, ztickangle.m, zticklabels.m,
zticks.m, ellipsoid.m, isocolors.m, isonormals.m, stairs.m, surfnorm.m,
__actual_axis_position__.m, __pltopt__.m, close.m, graphics_toolkit.m, pan.m,
print.m, printd.m, __ghostscript__.m, __gnuplot_print__.m, __opengl_print__.m,
rotate3d.m, subplot.m, zoom.m, compan.m, conv.m, poly.m, polyaffine.m,
polyder.m, polyint.m, polyout.m, polyreduce.m, polyvalm.m, roots.m, prefdir.m,
prefsfile.m, profexplore.m, profexport.m, profshow.m, powerset.m, unique.m,
arch_rnd.m, arma_rnd.m, autoreg_matrix.m, bartlett.m, blackman.m, detrend.m,
durbinlevinson.m, fftconv.m, fftfilt.m, fftshift.m, fractdiff.m, hamming.m,
hanning.m, hurst.m, ifftshift.m, rectangle_lw.m, rectangle_sw.m, triangle_lw.m,
sinc.m, sinetone.m, sinewave.m, spectral_adf.m, spectral_xdf.m, spencer.m,
ilu.m, __sprand__.m, sprand.m, sprandn.m, sprandsym.m, treelayout.m, beta.m,
betainc.m, betaincinv.m, betaln.m, cosint.m, expint.m, factorial.m, gammainc.m,
gammaincinv.m, lcm.m, nthroot.m, perms.m, reallog.m, realpow.m, realsqrt.m,
sinint.m, hadamard.m, hankel.m, hilb.m, invhilb.m, magic.m, pascal.m, rosser.m,
toeplitz.m, vander.m, wilkinson.m, center.m, corr.m, cov.m, discrete_cdf.m,
discrete_inv.m, discrete_pdf.m, discrete_rnd.m, empirical_cdf.m,
empirical_inv.m, empirical_pdf.m, empirical_rnd.m, kendall.m, kurtosis.m,
mad.m, mean.m, meansq.m, median.m, mode.m, moment.m, range.m, ranks.m,
run_count.m, skewness.m, spearman.m, statistics.m, std.m, base2dec.m,
bin2dec.m, blanks.m, cstrcat.m, deblank.m, dec2base.m, dec2bin.m, dec2hex.m,
hex2dec.m, index.m, regexptranslate.m, rindex.m, strcat.m, strjust.m,
strtrim.m, strtrunc.m, substr.m, untabify.m, __have_feature__.m,
__prog_output_assert__.m, __run_test_suite__.m, example.m, fail.m, asctime.m,
calendar.m, ctime.m, date.m, etime.m:
Add return arguments to @deftypefn macros where they were missing. Rename
variables in functions (particularly generic "retval") to match documentation.
Rename some return variables for (hopefully) better clarity (e.g., 'ax' to 'hax'
to indicate it is a graphics handle to an axes object).
| author | Rik <rik@octave.org> |
|---|---|
| date | Wed, 30 Mar 2022 20:40:27 -0700 |
| parents | 796f54d4ddbf |
| children | 597f3ee61a48 |
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######################################################################## ## ## Copyright (C) 2008-2022 The Octave Project Developers ## ## See the file COPYRIGHT.md in the top-level directory of this ## distribution or <https://octave.org/copyright/>. ## ## This file is part of Octave. ## ## Octave is free software: you can redistribute it and/or modify it ## under the terms of the GNU General Public License as published by ## the Free Software Foundation, either version 3 of the License, or ## (at your option) any later version. ## ## Octave is distributed in the hope that it will be useful, but ## WITHOUT ANY WARRANTY; without even the implied warranty of ## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ## GNU General Public License for more details. ## ## You should have received a copy of the GNU General Public License ## along with Octave; see the file COPYING. If not, see ## <https://www.gnu.org/licenses/>. ## ######################################################################## ## -*- texinfo -*- ## @deftypefn {} {@var{r} =} expm (@var{A}) ## Return the exponential of a matrix. ## ## The matrix exponential is defined as the infinite Taylor series ## @tex ## $$ ## \exp (A) = I + A + {A^2 \over 2!} + {A^3 \over 3!} + \cdots ## $$ ## @end tex ## @ifnottex ## ## @example ## expm (A) = I + A + A^2/2! + A^3/3! + @dots{} ## @end example ## ## @end ifnottex ## However, the Taylor series is @emph{not} the way to compute the matrix ## exponential; see @nospell{Moler and Van Loan}, @cite{Nineteen Dubious Ways ## to Compute the Exponential of a Matrix}, SIAM Review, 1978. This routine ## uses Ward's diagonal Pad@'e approximation method with three step ## preconditioning (SIAM Journal on Numerical Analysis, 1977). Diagonal ## Pad@'e approximations are rational polynomials of matrices ## @tex ## $D_q(A)^{-1}N_q(A)$ ## @end tex ## @ifnottex ## ## @example ## @group ## -1 ## D (A) N (A) ## @end group ## @end example ## ## @end ifnottex ## whose Taylor series matches the first ## @tex ## $2 q + 1 $ ## @end tex ## @ifnottex ## @code{2q+1} ## @end ifnottex ## terms of the Taylor series above; direct evaluation of the Taylor series ## (with the same preconditioning steps) may be desirable in lieu of the ## Pad@'e approximation when ## @tex ## $D_q(A)$ ## @end tex ## @ifnottex ## @code{Dq(A)} ## @end ifnottex ## is ill-conditioned. ## @seealso{logm, sqrtm} ## @end deftypefn function r = expm (A) if (nargin < 1) print_usage (); endif if (! isnumeric (A) || ! issquare (A)) error ("expm: A must be a square matrix"); endif if (isempty (A)) r = A; return; elseif (isscalar (A)) r = exp (A); return; elseif (isdiag (A)) r = diag (exp (diag (A))); return; endif n = rows (A); id = eye (n); ## Trace reduction. A(A == -Inf) = -realmax (); trshift = trace (A) / n; if (trshift > 0) A -= trshift * id; endif ## Balancing. [d, p, aa] = balance (A); [~, e] = log2 (norm (aa, "inf")); s = max (0, e); s = min (s, 1023); aa *= 2^(-s); ## Pade approximation for exp(A). c = [5.0000000000000000e-1, ... 1.1666666666666667e-1, ... 1.6666666666666667e-2, ... 1.6025641025641026e-3, ... 1.0683760683760684e-4, ... 4.8562548562548563e-6, ... 1.3875013875013875e-7, ... 1.9270852604185938e-9]; a2 = aa^2; x = (((c(8) * a2 + c(6) * id) * a2 + c(4) * id) * a2 + c(2) * id) * a2 + id; y = (((c(7) * a2 + c(5) * id) * a2 + c(3) * id) * a2 + c(1) * id) * aa; r = (x - y) \ (x + y); ## Undo scaling by repeated squaring. for k = 1:s r ^= 2; endfor ## inverse balancing. d = diag (d); r = d * r / d; r(p, p) = r; ## Inverse trace reduction. if (trshift > 0) r *= exp (trshift); endif endfunction %!assert (norm (expm ([1 -1;0 1]) - [e -e; 0 e]) < 1e-5) %!assert (expm ([1 -1 -1;0 1 -1; 0 0 1]), [e -e -e/2; 0 e -e; 0 0 e], 1e-5) %!assert (expm ([]), []) %!assert (expm (10), exp (10)) %!assert (full (expm (eye (3))), expm (full (eye (3)))) %!assert (full (expm (10*eye (3))), expm (full (10*eye (3))), 8*eps) %!assert (expm (zeros (3)), eye (3)) ## Test input validation %!error <Invalid call> expm () %!error <expm: A must be a square matrix> expm ({1}) %!error <expm: A must be a square matrix> expm ([1 0;0 1; 2 2])